JP2012113980A - Organic el display - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an organic EL display allowing easy adjustment of desired white balance and displaying high-quality image.SOLUTION: An organic EL display includes a plurality of pixels, organic EL elements, data line drivers, pixel circuits and gate line drivers. The respective plurality of pixels have at least three organic EL elements and emit at least three colors. Each of the pixels comprises two organic EL elements emitting a same color: a first organic EL element with an element having a high light-condensation ability disposed at a light emission surface side; and a second organic EL element without an element having a high light-condensation ability disposed at the light emission surface side. The organic EL display has means for, in each pixel, differentiating luminous ratios of the respective colors in the first and second organic EL elements.

Description

  The present invention relates to a display device using an organic EL (Electroluminescent) element, and more particularly to an active matrix organic EL display device capable of increasing the light use efficiency from the front of the organic EL element.

  In an organic EL element, light is emitted from the light emitting layer at various angles, so that a large amount of light components are totally reflected at the boundary surface between the protective layer and the external space. Among the totally reflected light components, There are components that get trapped. For this reason, there existed a subject that light extraction efficiency became low. In order to solve this problem, in Patent Document 1, a microlens array made of a resin is disposed on a silicon oxynitride (SiNxOy) film that seals an organic EL element.

Japanese Patent Laid-Open No. 2004-039500

  In the case of a configuration in which a microlens array is arranged on an organic EL element as in Patent Document 1, in addition to the effect that a light component that has been totally reflected can be taken out if there is no microlens array, there is an effect of condensing light. I can expect. Due to these effects, it is possible to improve the front luminance (light extraction efficiency in the front direction, that is, the normal direction of the substrate) of the display device using the organic EL element. However, the condensing effect of the microlens varies depending on the wavelength (R, G, B).

  Therefore, the chromaticity in the front direction differs between when the microlens is present and when it is absent. For this reason, the organic EL element with a microlens cannot obtain a desired white balance at the same luminance ratio as the organic EL element without a microlens. Therefore, in order to obtain a desired white balance, it is necessary to adjust the white balance by changing the ratio of R luminance, G luminance, and B luminance between an organic EL element with a microlens and an organic EL element without a microlens.

  Therefore, an object of the present invention is to provide an organic EL display device that can easily adjust a desired white balance and has high display image quality.

  In order to solve the above problems, the present invention provides a plurality of pixels arranged in a matrix, an organic EL element arranged in each pixel, and data for supplying a data signal corresponding to image data to each pixel. A line driver, a pixel circuit disposed in each of the pixels, having a plurality of transistors, supplying a driving current corresponding to a data signal to the organic EL element, and driving the organic EL element; Each pixel has three or more organic EL element groups each including two organic EL elements that emit the same color, and emits three or more colors. The two organic EL elements are a first organic EL element in which an element having a high light condensing property is arranged on the light emission surface side, and an element having a high light condensing property is not arranged on the light emission surface side. Second organic EL An organic EL display device comprising: a plurality of sub-pixels; and a means for differentiating a luminance ratio of each color for the first organic EL element and a luminance ratio of each color for the second organic EL element in each pixel. It is to provide.

  According to the present invention, the ratio of R luminance, G luminance, and B luminance can be calculated from the common image data in a “region with a highly condensing element” and a “region without a highly condensing element” within one pixel. Can be different. Thereby, a desired white balance can be easily adjusted, and an organic EL display device with high display image quality can be realized.

It is the schematic which shows the organic electroluminescent panel concerning this invention, a pixel structure, and pixel arrangement | positioning. It is the relative luminance-viewing angle characteristic of the subpixel containing the organic EL element which concerns on this invention. It is an operation | movement timing chart for every mode of the organic electroluminescent panel which concerns on this invention. It is a relative luminance-viewing angle characteristic for every mode of the organic EL panel according to the present invention. It is a relative electric power characteristic for every mode of the organic electroluminescent panel which concerns on this invention. It is a relative drive current characteristic for every mode of the organic electroluminescent panel which concerns on this invention. 1 is a schematic diagram of an organic EL panel, pixel configuration, and pixel arrangement of Example 1. FIG. 2 is a pixel circuit according to the first exemplary embodiment. 3 is an operation timing chart of the organic EL panel of Example 1. 6 is a schematic diagram of an organic EL panel of Example 2. FIG. 2 is a pixel circuit of Example 2. FIG. It is an example of a means for generating two data signals from one image data. 6 is an operation timing chart of the organic EL panel of Example 2. 6 is a pixel circuit according to Embodiment 3. 12 is an operation timing chart of the organic EL panel of Example 3. 6 is a pixel circuit of Example 4. FIG. 10 is an operation timing chart of the organic EL panel of Example 4.

  Hereinafter, preferred embodiments of the organic EL display device of the present invention will be described with reference to the drawings.

  FIG. 1A is a schematic diagram of an organic EL panel 11 having a plurality of pixels (m rows and n columns pixels) arranged in a matrix, and an organic EL element is arranged in each pixel. It is an example of an organic EL panel. The organic EL panel 11 includes a data line driving circuit 12 that applies a data signal to the data line 15 and a gate line driving circuit 13 that drives the gate line 16. The pixel circuit 14 is disposed in each pixel, includes a plurality of transistors, supplies a driving current corresponding to a data signal to the organic EL element, and turns on the organic EL element. The m rows and n columns pixels are arranged at the intersections of the data lines and the gate lines, and display is performed based on the data signals corresponding to the pixels.

  The data line driving circuit 12 is a data line driver that supplies a data signal corresponding to image data to each pixel, and is a circuit that inputs image data from the outside and controls the amount of current that drives the organic EL element according to the image data. It is. The gate line driving circuit 13 is a gate line driver that drives each transistor included in the pixel circuit 14 (drives the gate line 16 connected to the gate terminal of each transistor), and generates a pulse signal at the time of writing operation in the corresponding row. . In general, since a write operation is sequentially performed from the first row, a shift register and other logic circuits are mounted, and a logic signal is generated so that the pixel circuit 14 can perform a write operation. The pixel in the row to which writing is performed by the gate line driving circuit 13 inputs a data signal driven by the data line driving circuit 12 from the data line 15 and performs a writing operation.

  FIG. 1B is a partial cross-sectional view showing a portion corresponding to a pixel (for example, a row and b column in FIG. 1A) in the display device of the present invention. The pixel of the display device of the present invention has a plurality of subpixels. Here, the “subpixel” means a region where one light emitting element is provided. Although FIG. 1B shows a top emission type display device that extracts light from the upper surface of the organic EL element formed on the substrate (from the upper direction), the present invention also applies to a bottom emission type display device. Applicable.

  In the present invention, an organic EL element as a light emitting element is formed in each of the plurality of sub-pixels, and the plurality of sub-pixels included in the same pixel have different viewing angle characteristics (viewing angle characteristics A and viewing angle characteristics B). . Specifically, each pixel has two sub-pixels that emit the same color, and the light-emitting surface side of the organic EL element provided in one of the two sub-pixels has a light condensing property. High elements are arranged. In addition, each pixel is a pixel that is provided in each of the two sub-pixels and has three or more organic EL element groups each including two organic EL elements that emit the same color, and emits three or more colors. The two organic EL elements constituting the organic EL element group include a first organic EL element (hereinafter, referred to as an organic EL element B) in which a highly condensing element is disposed on the light emission surface side, and a light emission surface side. This is a second organic EL element (hereinafter referred to as organic EL element A) in which no highly condensing element is disposed. It is preferable to use a microlens or the like as an element having a high light collecting property. Alternatively, the distance between the pair of electrodes is changed so that one of the organic EL elements A and B has a strengthening interference effect in the front direction, and the other element is strengthened in an oblique direction (direction other than the front). An interference effect may be provided.

  A region separation layer 22 for separating regions is provided between the organic EL elements in different regions. Each of the organic EL elements includes a pair of electrodes, an anode electrode 21 and a cathode electrode 24, and an organic compound layer 23 including a light emitting layer (hereinafter referred to as “organic EL layer”) sandwiched between the electrodes. ing. Specifically, an anode electrode 21 patterned for each organic EL element is formed on the substrate 20, an organic EL layer 23 is formed on the anode electrode 21, and a cathode electrode 24 is further formed on the organic EL layer 23. Is formed.

  The anode electrode 21 is formed from a conductive metal material having a high reflectance such as Ag. Or you may comprise from the laminated body of the layer which consists of transparent conductive materials, such as a layer which consists of such a metal material, and ITO (Indium-Tin-Oxide) excellent in the hole injection characteristic.

  The cathode electrode 24 is formed in common for a plurality of organic EL elements, and has a semi-reflective or light-transmitting configuration capable of extracting light emitted from the light emitting layer to the outside of the element. Specifically, when the cathode electrode 24 has a semi-reflective configuration in order to enhance the interference effect inside the device, the cathode electrode 24 is made of a conductive metal material having excellent electron injection properties such as Ag and AgMg. It is comprised by forming a layer with a film thickness of 2-50 nm. In addition, “semi-reflective” means a property of reflecting a part of the light emitted inside the element and transmitting a part thereof, and having a reflectance of 20 to 80% with respect to visible light, “Light transmissivity” means a material having a transmittance of 80% or more with respect to visible light.

  The organic EL layer 23 includes a single layer or a plurality of layers including at least a light emitting layer. Examples of the configuration of the organic EL layer 23 include a four-layer configuration including a hole transport layer, a light-emitting layer, an electron transport layer and an electron injection layer, and a three-layer configuration including a hole transport layer, a light-emitting layer and an electron transport layer. It is done. A known material can be used as the material constituting the organic EL layer 23.

  A pixel circuit is formed on the substrate 20 so that each organic EL element can be driven independently. These pixel circuits are composed of a plurality of thin film transistors (hereinafter referred to as TFT: Thin-Film-Transistor) (not shown). The substrate 20 on which the TFT is formed is covered with an interlayer insulating film in which a contact hole for electrically connecting the TFT and the anode electrode 21 is formed (not shown). A flattening film is formed on the interlayer insulating film to absorb surface irregularities caused by the pixel circuit and flatten the surface (not shown).

  A protective layer 25 is formed on the cathode electrode 24 in order to protect the organic EL layer 23 from oxygen and moisture in the air. The protective layer 25 is made of an inorganic material such as SiN or SiON. Or it consists of a laminated film of an inorganic material and an organic material. The thickness of the inorganic film is preferably 0.1 μm or more and 10 μm or less, and is preferably formed by a CVD method. The organic film is preferably 1 μm or more because it is used to improve the protection performance by covering foreign matters that adhere to the surface during the process and cannot be removed. In FIG. 1B, the protective layer 25 is formed along the shape of the pixel separation layer 22, but the surface of the protective layer 25 may be flat. By using an organic material, the surface can be easily flattened.

  The display device of the present invention may be configured as an organic EL panel having three different hues, or may be configured as an organic EL panel having not only three hues but four different hues. In the case of three hues, for example, an organic EL panel having three hues of R, G, and B may be used, and the organic EL panel may be composed of R, G, and B three hues. -It is good also as a structure which piled up the color filter of 3 hues of G and B. In this case, a pixel unit composed of pixels that display the hues of R, G, and B is a display unit. In the case of four hues, for example, an organic EL panel having four hues of R, G, B, and W may be used.

  FIG. 1C shows an example of the pixel arrangement of the organic EL panel of the present invention. The R pixel 31, the G pixel 32, and the B pixel 33 are arranged, and the R pixel 31, the G pixel 32, and the B pixel 33 constitute an organic EL panel that constitutes one pixel unit. The R pixel 31 includes an R-1 sub-pixel 311 and an R-2 sub-pixel 312, and each sub-pixel has a hue R and different optical characteristics. The G pixel 32 includes a G-1 sub-pixel 321 and a G-2 sub-pixel 322, and each sub-pixel has a hue of G and different optical characteristics. The B pixel 33 includes a B-1 sub-pixel 331 and a B-2 sub-pixel 332, and each sub-pixel has a hue of B and different optical characteristics. Each pixel has two sub-pixels that emit R and have different optical characteristics, two sub-pixels that emit G and have different optical characteristics, and two sub-pixels that emit B and have different optical characteristics.

  Hereinafter, the R-1 subpixel 311, the G-1 subpixel 321, and the B-1 subpixel 331 are formed by the subpixel A having a wide viewing angle, and the R-2 subpixel 312 and the G-2 subpixel 322 are formed. A case where the B-2 subpixel 332 is formed by the subpixel B having a high front luminance characteristic will be described. Here, the characteristic with high front luminance means a characteristic with high light extraction efficiency in the front direction, that is, the normal direction of the substrate.

  2 shows the relative luminance-viewing angle characteristics of each of the sub-pixels A and B. FIG. 2A shows the relative luminance-viewing-angle characteristics of the sub-pixel A, and FIG. 2B shows the relative luminance-viewing-angle characteristics of the sub-pixel B. Shows angular characteristics. The luminance is expressed as a relative luminance value when the same current is injected into the subpixels A and B and the front luminance of the subpixel A is 1. From FIG. 2, the subpixel A has a wide viewing angle. On the other hand, although the subpixel B has a narrow viewing angle, the front luminance is about four times that of the subpixel A.

  Next, the operation of the organic EL panel 11 will be described. Two sub-pixels having different optical characteristics of each of the R, G, and B pixels are driven by a pixel circuit that can be independently turned on / off (light emission / non-light emission). For example, in the R pixel, the R-1 subpixel and the R-2 subpixel can be turned on / off independently.

  The luminance ratio (light emission ratio) of the R-1 subpixel 311, the G-1 subpixel 321, and the B-1 subpixel 331, and the R-2 subpixel 312, the G-2 subpixel 322, and the B-2 subpixel 332 If the lighting is performed with different luminance ratios, a desired white balance can be obtained and high image quality can be realized. Since there is a difference in chromaticity in the front direction when there is an element having high light condensing properties such as a microlens, a desired white balance can be obtained by lighting as described above. In order to obtain a desired white balance, the present invention includes means for differentiating the luminance ratio of each color for the organic EL element A and the luminance ratio of each color for the organic EL element B in each pixel.

  Driving in the following three modes is more preferable in that display according to the user scene can be performed and high image quality can be realized.

  When only the R-1 subpixel 311, the G-1 subpixel 321, and the B-1 subpixel 331, which are regions having a wide viewing angle and optical characteristics, are lit, the organic EL panel 11 has a wide viewing angle performance. (Hereinafter referred to as “wide viewing angle mode”).

  When only the R-2 sub-pixel 312, the G-2 sub-pixel 322, and the B-2 sub-pixel 332, which are regions having a narrow viewing angle but high front luminance optical characteristics, are turned on, the organic EL panel 11 is in front. High luminance performance is obtained (hereinafter referred to as “outdoor visibility mode”).

  The R-2 sub-pixel 312, the G-2 sub-pixel 322, and the B-2 sub-pixel 332 are lit at a low current, and the front luminance is set to the R-1 sub-pixel 311, the G-1 sub-pixel 321, and the B-1 sub-pixel 331. The power consumption can be reduced (hereinafter referred to as “power saving mode”).

  Furthermore, if the sub-pixels A and B are turned on in an intermediate state between the “wide viewing angle mode” and the “outdoor visibility mode”, and an intermediate state between the “wide viewing angle mode” and the “power saving mode”, the user It is more preferable in that various displays can be performed according to the scene and high image quality can be realized.

  Therefore, it is more preferable that the organic EL elements A and B of the same color have means for making one or both of the lighting time and the driving current different from each other in that the above effect can be obtained.

  For example, the pixel circuits shown in FIGS. 8, 11, and 14 are preferably used as the pixel circuits that are driven in the above three modes. In any of the three modes, two subpixels having the same color and different optical characteristics are driven by common image data. The lighting time / driving current in each sub-pixel is changed according to the above-described optical characteristics based on the relative characteristics of the front luminance and the peripheral luminance and the above three modes.

  Hereinafter, details will be described in specific embodiments, but the present invention is not limited to the following four embodiments.

[First Embodiment]
The display device of this embodiment has the organic EL panel of FIG. 1A, the pixel configuration of FIG. 1B, and the pixel arrangement of FIG. The R-1 subpixel 311, the G-1 subpixel 321, and the B-1 subpixel 331 in FIG. 1C are formed by the subpixel A having a wide viewing angle characteristic. The R-2 subpixel 312, the G-2 subpixel 322, and the B-2 subpixel 332 in FIG. 1C are formed by the subpixel B having a high front luminance (light extraction efficiency in the front direction) characteristic. . For example, it is preferable that the surface of the sub-pixel including the organic EL element A is a flat surface, and an element having a high light collecting property such as a micro lens is formed in the sub-pixel including the organic EL element B. The relative luminance-viewing angle characteristics of the sub-pixel including the organic EL element A and the sub-pixel including the organic EL element B are as shown in FIG. As the pixel circuit, for example, the pixel circuit of FIG. 8 is preferably used.

  In this embodiment, in order to obtain a desired white balance, the luminance ratio of each color for the organic EL element A and the luminance ratio of each color for the organic EL element B are made different. Specifically, the data line 15 in FIG. 1A writes the same data signal to the organic EL elements A and B of the same color, and the luminance ratio of each color in the organic EL elements A and B is different in each pixel circuit. Make it. As means for varying the luminance ratio of each color in the organic EL elements A and B in each pixel circuit, for example, TFT (M2) and TFT (M5) having different transistor sizes (W / L ratios) in FIG. is there. In this case, the current drive capability differs between the organic EL elements A and B.

  Here, it is assumed that the current drive capability of the TFT (M2) of the R pixel is DR1, the current drive capability of the TFT (M2) of the G pixel is DG1, and the current drive capability of the TFT (M2) of the B pixel is DB1. Also, the current drive capability of the R pixel TFT (M5) is DR2, the current drive capability of the G pixel TFT (M5) is DG2, and the current drive capability of the B pixel TFT (M5) is DB2. In FIG. 8, DR1: DG1: DB1 and DR2: DG2: DB2, which are current drive capability ratios, are different. By making DR1: DG1: DB1 and DR2: DG2: DB2 different, it is possible to adjust the white balance by making the drive currents different in the organic EL elements A and B. That is, even if the same voltage data Vdata is input as a data signal to the R pixel, G pixel, and B pixel, the luminance balance of the R pixel, G pixel, and B pixel can be changed according to the current drive capability ratio. The white balance can be adjusted to a desired value.

  When obtaining a desired white balance, the drive current ratio required for the R pixel, G pixel, and B pixel is IR1: IG1: IB1 for the organic EL element A, and IR2: IG2: IB2 for the organic EL element B. In this case, DR1: DG1: DB1 = IR1: IG1: IB1, or DR2: DG2: DB2 = IR2: IG2: IB2. At this time, the luminance is LR1: LG1: LB1 ≠ LR2: LG2: LB2. LR1 is the luminance of the organic EL element A in the R pixel, LG1 is the luminance of the organic EL element A in the G pixel, and LB1 is the luminance of the organic EL element A in the B pixel. LR2 is the luminance of the organic EL element B in the R pixel, LG2 is the luminance of the organic EL element B in the G pixel, and LB2 is the luminance of the organic EL element B in the B pixel. That is, the luminance ratio of each color in the organic EL elements A and B is varied so that LR1: LG1: LB1 ≠ LR2: LG2: LB2.

  Thus, in this embodiment, since the luminance ratio of each color in the organic EL elements A and B can be made different, white balance can be adjusted and high image quality can be realized.

  In the present embodiment, it is more preferable that the lighting times of the organic EL elements A and B of the same color are different from each other in that display according to the user scene can be performed and high image quality can be realized. Specifically, the data line 15 in FIG. 1A writes the same data signal to the organic EL elements A and B of the same color, and the lighting time in the organic EL elements A and B of the same color is set in each pixel circuit. Make it different. As means for changing the lighting times of the organic EL elements A and B of the same color in each pixel circuit, the organic EL elements A and B of the same color are connected separately to the organic EL elements A and B of the same color. It is preferable to separately control the lighting and extinguishing of each. Examples of the means are P2 and TFT (M3) and P3 and TFT (M4) in FIG. M3 and M4 are switches that are provided on the path for supplying the drive current to the organic EL elements A and B, respectively, and control the flow of the drive current, and ON / OFF is separately controlled by the selection control lines P2 and P3. . Hereinafter, this more preferable aspect is demonstrated using FIG.

  FIG. 3 is an operation timing chart for each mode of the organic EL panel of the present embodiment. In FIG. 3, the horizontal axis represents time, and the vertical axis represents lighting ON (HI) / OFF (LOW). In FIG. 2, the front luminance is assumed to be subpixel (a) including organic EL element A: subpixel (b) including organic EL element B = 1: 4, and the relationship between peripheral luminance and power is set as a setting condition. The setting conditions are as follows.

  First, a case where “wide viewing angle mode” and “power saving mode” can be selected will be described. When realizing these two modes, the front luminance of the sub-pixel including the organic EL element A and the sub-pixel including the organic EL element B are made the same. Here, in FIG. 3, the power ratio of each mode per frame is (a) :( b) :( c) :( d) :( e) = 5: 16: 13: 10: 7: 4 Assume the mode shown. In this case, (a) is (lighting time of organic EL element A) :( lighting time of organic EL element B) = 16: 0, similarly (b) is 12: 1, (c) is 8: 2, ( d) is 4: 3, and (e) is 0: 4. The ratio of the current / time product of the organic EL element A and the organic EL element B per frame is as follows: (a) is 4: 0, (b) is 3: 1, (c) is 2: 2, d) is 1: 3, and (e) is 0: 4. The drive current input from the pixel circuit is the same at any lighting timing.

  FIG. 4 shows the relative luminance-viewing angle characteristics and FIG. 5 shows the relative power characteristics when the lamp is lit in this way. FIGS. 4A to 4E and FIGS. 5A to 5E correspond to FIGS. 3A to 3E. As can be seen from FIG. 4, the viewing angle becomes wider as the transition from (e) to (a), and from FIG. 5, the power consumption can be suppressed as the transition from (a) to (e). Accordingly, the “wide viewing angle mode” can be selected by lighting as shown in (a), and the “power saving mode” can be selected by lighting as shown in (e), and (b) to (d) It is possible to select an intermediate state between the “wide viewing angle mode” and the “power saving mode”. For this reason, high image quality can be realized.

  Next, a case where “wide viewing angle mode” and “outdoor visibility mode” can be selected will be described. When realizing these two modes, the front luminance of the sub-pixel including the organic EL element A and the sub-pixel including the organic EL element B are not the same. Here, it is assumed that the power ratio of each mode per frame indicates five modes of (a) :( b) :( c) :( d) :( e) = 4: 7: 10: 13: 16. To do. In this case, (a) is (lighting time of organic EL element A) :( lighting time of organic EL element B) = 4: 0, similarly (b) is 3: 4, (c) is 2: 8, d) is 1:12, and (e) is 0:16. The ratio of the current / time product of the organic EL element A and the organic EL element B per frame is as follows: (a) is 4: 0, (b) is 3: 1, (c) is 2: 2, d) is 1: 3, and (e) is 0: 4.

  When lit in this way, the viewing angle becomes wider as the transition from (e) to (a), and the front luminance increases as the transition from (a) to (e). Accordingly, the “wide viewing angle mode” can be selected by lighting as shown in (a), the “outdoor visibility mode” can be selected by lighting as shown in (e), and (b) to (d). It is possible to select an intermediate state between the “wide viewing angle mode” and the “outdoor visibility mode”. For this reason, high image quality can be realized.

  Further, in this embodiment, the number of times of writing to the organic EL elements A and B of the same color with the same data line can be reduced to one, so that the layout efficiency is improved by simplifying the peripheral circuit and sharing the wiring and the like. be able to. Further, since the signal level of the data line 15 can ensure substantially the same dynamic range for the organic EL elements A and B of the same color, the S / N ratio can be increased.

[Second Embodiment]
The display device of this embodiment is the same as that of the first embodiment except that the pixel circuit is different. As the pixel circuit, for example, the pixel circuit of FIG. 11 is preferably used.

  In this embodiment, in order to obtain a desired white balance, the luminance ratio of each color for the organic EL element A and the luminance ratio of each color for the organic EL element B are made different. Specifically, each data signal is generated for the organic EL elements A and B of the same color by the data line driving circuit 12 in FIG. -The luminance ratio of each color in B is varied. As means for varying the luminance ratio of each color in the organic EL elements A and B in the data line driving circuit 12 (in the data line driver), the gate terminals of the driving transistors included in the organic EL elements A and B of the same color are used. Means for generating and supplying different data signals are preferred. In this case, each pixel circuit is preferably provided with means for holding a data signal corresponding to each of the organic EL elements A and B. By making the data signals different, it is possible to adjust the white balance by making the drive currents different in the organic EL elements A and B. An operation timing chart of the organic EL panel is shown in Example 2.

  The current drive capability ratio of the organic EL elements A and B is as described in the first embodiment. When obtaining a desired white balance, the data signals corresponding to the organic EL elements A in the R pixel, G pixel, and B pixel and the organic EL elements B in the R pixel, G pixel, and B pixel are different from each other. Make it. The drive current ratio required for the R pixel, G pixel, and B pixel is IR1: IG1: IB1 for the organic EL element A, and IR2: IG2: IB2 for the organic EL element B. In this case, IR1 / IR2 ≠ IG1 / IG2 ≠ IB1 / IB2. At this time, the luminance is LR1 / LR2 ≠ LG1 / LG2 ≠ LB1 / LB2. LR1 is the luminance of the organic EL element A in the R pixel, LG1 is the luminance of the organic EL element A in the G pixel, and LB1 is the luminance of the organic EL element A in the B pixel. LR2 is the luminance of the organic EL element B in the R pixel, LG2 is the luminance of the organic EL element B in the G pixel, and LB2 is the luminance of the organic EL element B in the B pixel. That is, the luminance ratio of each color in the organic EL elements A and B is made different so that LR1 / LR2 ≠ LG1 / LG2 ≠ LB1 / LB2.

  Thus, in this embodiment, since the luminance ratio of each color in the organic EL elements A and B can be made different, white balance can be adjusted and high image quality can be realized.

  In the present embodiment, it is more preferable that the organic EL elements A and B of the same color have the same lighting time and different drive currents because display according to the user scene can be performed and high image quality can be realized. More specifically, each data signal is generated for the organic EL elements A and B of the same color by the data line driving circuit 12 in FIG. Thus, the drive currents supplied to the organic EL elements A and B of the same color can be realized differently. For example, it can be realized by means for generating and supplying different data signals to the gate terminals of the drive transistors included in the organic EL elements A and B of the same color. Hereinafter, this more preferable aspect is demonstrated using FIG.

  FIG. 6 shows relative drive current characteristics for each mode of the organic EL panel of the present embodiment. In FIG. 6, the horizontal axis represents each mode, and the vertical axis represents the relative drive current of the organic EL elements A and B. In FIG. 2, the front luminance is assumed to be subpixel (a) including organic EL element A: subpixel (b) including organic EL element B = 1: 4, and the relationship between peripheral luminance and power is set as a setting condition. The setting conditions are as follows.

  First, a case where “wide viewing angle mode” and “power saving mode” can be selected will be described. When realizing these two modes, the front luminance of the sub-pixel including the organic EL element A and the sub-pixel including the organic EL element B are made the same as described above. Here, in FIG. 6, the power ratio of each mode per frame is (a) :( b) :( c) :( d) :( e) = 5: 16: 13: 10: 7: 4 Assume the mode shown. In this case, (a) is (driving current of organic EL element A) :( driving current of organic EL element B) = 16: 0, similarly (b) is 12: 1, (c) is 8: 2, ( d) is 4: 3, and (e) is 0: 4. The ratio of the current / time product of the organic EL element A and the organic EL element B per frame is as follows: (a) is 4: 0, (b) is 3: 1, (c) is 2: 2, d) is 1: 3, and (e) is 0: 4.

  The relative luminance-viewing angle characteristic and relative power characteristic when the lamp is lit in this way are as shown in FIGS. 4 and 5, respectively. (A) to (e) in FIG. 4 and (a) to (e) in FIG. 5 correspond to (a) to (e) in FIG. Therefore, similarly to the first embodiment, the viewing angle increases as the transition from (e) to (a), and the power consumption can be suppressed as the transition from (a) to (e). Accordingly, as in the first embodiment, the “wide viewing angle mode” and the “power saving mode” can be selected, and an intermediate state between the “wide viewing angle mode” and the “power saving mode” can be selected. High image quality can be achieved.

  Next, a case where “wide viewing angle mode” and “outdoor visibility mode” can be selected will be described. When realizing these two modes, the front luminance of the sub-pixel including the organic EL element A and the sub-pixel including the organic EL element B are not made the same as described above. Here, it is assumed that the power ratio of each mode per frame indicates five modes of (a) :( b) :( c) :( d) :( e) = 4: 7: 10: 13: 16. To do. In this case, (a) is (drive current of organic EL element A) :( drive current of organic EL element B) = 4: 0, similarly (b) is 3: 4, (c) is 2: 8, ( d) is 1:12, and (e) is 0:16. The ratio of the current / time product of the organic EL element A and the organic EL element B per frame is as follows: (a) is 4: 0, (b) is 3: 1, (c) is 2: 2, d) is 1: 3, and (e) is 0: 4.

  When the light is turned on in this way, the viewing angle becomes wider as the state transitions from (e) to (a), and the front luminance increases as the state transitions from (a) to (e), as in the first embodiment. Accordingly, as in the first embodiment, “wide viewing angle mode” and “outdoor visibility mode” can be selected, and an intermediate state between “wide viewing angle mode” and “outdoor visibility mode” can be selected. Therefore, high image quality can be realized.

  In the present embodiment, detailed driving conditions can be set in each mode by the data line driving circuit 12, so that driving with higher usability can be performed. Furthermore, since the gamma characteristics and the like can be easily corrected for the organic EL elements A and B of the same color, high quality driving can be performed.

[Third Embodiment]
The display device of this embodiment is the same as that of the second embodiment except that the pixel circuit is different. For example, the pixel circuit of FIG. 14 is preferably used as the pixel circuit.

  In this embodiment, in order to obtain a desired white balance, the luminance ratio of each color for the organic EL element A and the luminance ratio of each color for the organic EL element B are made different. Specifically, the data line 15 in FIG. 1A writes the same data signal to the organic EL elements A and B of the same color, and the luminance ratio of each color in the organic EL elements A and B is different in each pixel circuit. Make it. As means for varying the luminance ratio of each color in the organic EL elements A and B in each pixel circuit, a different voltage (reference voltage) is applied to the gate terminal of each driving transistor for each organic EL element A and B of the same color. A means for supplying is preferred. Examples of such means are the voltages Vref1 and Vref2 applied to the gate terminal of the TFT (M2) which is the driving TFT and the gate terminal of the TFT (M6) in FIG. By varying the voltage, the white balance can be adjusted by varying the drive current in the organic EL elements A and B. The current drive capability ratio, drive current ratio, and luminance of the organic EL elements A and B are as described in the second embodiment. An operation timing chart of the organic EL panel is shown in Example 3.

  Thus, in this embodiment, since the luminance ratio of each color in the organic EL elements A and B can be made different, white balance can be adjusted and high image quality can be realized.

  In the present embodiment, it is more preferable that the organic EL elements A and B of the same color have the same lighting time and different drive currents because display according to the user scene can be performed and high image quality can be realized. Specifically, the data line 15 in FIG. 1A writes the same data signal to the organic EL elements A and B of the same color and supplies them to the organic EL elements A and B of the same color in each pixel circuit. This can be realized with different currents. For example, it can be realized by means for supplying different voltages (reference voltages) to the gate terminals of the drive transistors included in the organic EL elements A and B of the same color. Hereinafter, this more preferable aspect is demonstrated.

  The relative drive current characteristics for each mode of the organic EL panel in the present embodiment are as shown in FIG. In FIG. 2, the front luminance is assumed to be subpixel (a) including organic EL element A: subpixel (b) including organic EL element B = 1: 4, and the relationship between peripheral luminance and power is set as a setting condition. The setting conditions are as follows.

  First, a case where “wide viewing angle mode” and “power saving mode” can be selected will be described. As in the second embodiment, a mode is assumed in which the power ratio of each mode per frame shows five ways of 16: 13: 10: 7: 4. In this case, for the organic EL elements A and B, (a) is 16: 0, (b) is 12: 1, (c) is 8: 2, (d) is 4: 3, and (e) is 0: 4. Drive current ratio. The ratio of the current / time product of the organic EL element A and the organic EL element B per frame is as follows: (a) is 4: 0, (b) is 3: 1, (c) is 2: 2, d) is 1: 3, and (e) is 0: 4.

  When lit in this way, as in the second embodiment, the viewing angle increases as the transition from (e) to (a), and the power consumption can be suppressed as the transition from (a) to (e). Therefore, as in the second embodiment, the “wide viewing angle mode” and the “power saving mode” can be selected, and an intermediate state between the “wide viewing angle mode” and the “power saving mode” can be selected. High image quality can be achieved.

  Next, setting conditions when “wide viewing angle mode” and “outdoor visibility mode” can be selected will be described. As in the second embodiment, a mode is assumed in which the power ratio of each mode per frame shows five ways of 4: 7: 10: 13: 16. In this case, for the organic EL elements A and B, (a) is 4: 0, (b) is 3: 4, (c) is 2: 8, (d) is 1:12, and (e) is 0:16. Drive current ratio. The ratio of the current / time product of the organic EL element A and the organic EL element B per frame is as follows: (a) is 4: 0, (b) is 3: 1, (c) is 2: 2, d) is 1: 3, and (e) is 0: 4.

  When lit in this way, the viewing angle becomes wider as the transition from (e) to (a) is performed, and the front luminance becomes higher as the transition is made from (a) to (e), as in the second embodiment. Accordingly, as in the second embodiment, “wide viewing angle mode” and “outdoor visibility mode” can be selected, and an intermediate state between “wide viewing angle mode” and “outdoor visibility mode” can be selected. Therefore, high image quality can be realized.

  In the present embodiment, as in the first embodiment, the layout efficiency can be increased and the S / N ratio can be increased by simplifying peripheral circuits and sharing wirings.

[Fourth Embodiment]
The display device of this embodiment is the same as that of the second embodiment except that the pixel circuit is different. As the pixel circuit, for example, the pixel circuit of FIG. 16 is preferably used.

  In this embodiment, in order to obtain a desired white balance, the luminance ratio of each color for the organic EL element A and the luminance ratio of each color for the organic EL element B are made different. Specifically, the data line 15 in FIG. 1A writes the same data signal to the organic EL elements A and B of the same color, and the luminance ratio of each color in the organic EL elements A and B is different in each pixel circuit. Make it. As means for varying the luminance ratio of each color in the organic EL elements A and B in each pixel circuit, means for reducing the data signal written to the organic EL element B is preferable. An example of the means is the capacitor C3 in FIG. By reducing the pressure and making the data signals different, it is possible to adjust the white balance by making the drive currents different in the organic EL elements A and B. The current drive capability ratio, drive current ratio, and luminance of the organic EL elements A and B are as described in the second embodiment. An operation timing chart of the organic EL panel is shown in Example 4.

  Thus, in this embodiment, since the luminance ratio of each color in the organic EL elements A and B can be made different, white balance can be adjusted and high image quality can be realized.

  In the first to third embodiments, the mode switching is performed in five stages from (a) to (e) as shown in FIGS. 3 and 6, but the resolution can be increased, or (a) to ( It is also possible to vary step e) steplessly.

  Hereinafter, the present invention will be described in detail by way of examples.

[Example 1]
FIG. 7A is a schematic diagram of an organic EL panel 80 having a plurality of pixels (m rows and n columns pixels) arranged in a matrix, and an organic EL element is arranged in each pixel. It is an organic EL panel. The organic EL panel 80 includes an organic EL element (not shown), a data line driving circuit 81 (data line driver), a gate line driving circuit 82 (gate line driver), a pixel circuit 83, and a gate line driving circuit 84 (gate line driver). . The data line driving circuit 81 applies a data signal to the data line 85. The gate line driving circuit 82 drives the gate line P1. The pixel circuit 83 is disposed in each pixel, has a plurality of transistors, supplies a drive current corresponding to the data signal to the organic EL element, and turns on the organic EL element. The gate line driving circuit 84 drives the gate lines (selection control lines) P2 and P3 in the display area. Each pixel has two sub-pixels that emit R and have different optical characteristics, two sub-pixels that emit G and have different optical characteristics, and two sub-pixels that emit B and have different optical characteristics. Each subpixel includes an organic EL element. In FIG. 7A, the gate line driving circuit 82 and the display area gate line driving circuit 84 are arranged on the left and right sides of the pixel group. However, they may be arranged on either the left or right side, and the pixel writing operation is performed. In order to improve the quality, the same function may be arranged on both the left and right sides and driven from both sides.

  FIG. 7B is a partial cross-sectional view showing a portion corresponding to a pixel in the display device of this embodiment. The layers below the protective layer 25 have the same configuration as in FIG. The surface of the subpixel including the organic EL element A is a flat surface, and the microlens 111 is formed in the subpixel including the organic EL element B. The microlens 111 is formed by processing a resin material, and specifically can be formed by a method such as embossing.

  In a sub-pixel without a microlens, light emitted obliquely from the light emitting layer of the organic EL layer 23 is emitted obliquely when emitted from the protective layer 25, or is totally reflected and taken out to the outside. I can't. On the other hand, in the sub-pixel having the micro lens 111, the light emitted from the light emitting layer of the organic EL layer 23 is transmitted through the transparent cathode electrode 24, and then transmitted through the protective layer 25 and the micro lens 111 to be emitted to the outside. The

  When the microlens 111 is present, the emission angle is closer to the normal direction of the substrate than when the microlens is not present. Therefore, the condensing effect in the normal direction of the substrate is improved when the microlens 111 is present. That is, the light use efficiency in the front direction can be enhanced as the display device. In addition, when the microlens 111 is present, the incident angle of the light emitted obliquely from the light emitting layer with respect to the emission interface is close to the vertical, so that the total amount of light reflected is reduced. As a result, the light extraction efficiency is also improved.

  As described above, the organic EL panel 80 of the present embodiment includes a sub-pixel having a flat light emission surface side of the organic EL element, and a light emission surface side of the organic EL element (on the light extraction side, that is, the organic EL element in the case of the top emission type). A sub-pixel having a microlens formed on the upper side of the element. The sub-pixel including the organic EL element A has optical characteristics with a wide viewing angle because it does not have a microlens, and the sub-pixel including the organic EL element B has a microlens and thus has high front luminance (light extraction efficiency in the front direction). Has characteristics.

  FIG. 7C shows a pixel arrangement of the organic EL panel of this embodiment. The R pixel 101, the G pixel 102, and the B pixel 103 are arranged, and the organic EL panel is configured by one of the R pixel 101, the G pixel 102, and the B pixel 103 to form one pixel unit. The R pixel 101 is formed by an R-1 subpixel 1011 and an R-2 subpixel 1012, the G pixel 102 is formed by a G-1 subpixel 1021 and a G-2 subpixel 1022, and the B pixel 103 is formed by a B-1 subpixel. The pixel 1031 and the B-2 sub-pixel 1032 are formed. The R-1 subpixel 1011, the G-1 subpixel 1021, and the B-1 subpixel 1031 are subpixels having a flat light emission surface side, and are an R-2 subpixel 1012, a G-2 subpixel 1022, and a B-2 subpixel. The pixel 1032 is a subpixel in which a microlens is formed on the light emission surface side of the organic EL element. Relative luminance-viewing angle characteristics of the R-1 subpixel 1011, the G-1 subpixel 1021, and the B-1 subpixel 1031 and the R-2 subpixel 1012, the G-2 subpixel 1022, and the B-2 subpixel 1032 The relative luminance-viewing angle characteristics are as shown in (a) and (b) of FIG.

  FIG. 8 shows a pixel circuit of this embodiment. The gate line P1 is connected to the gate terminal of the TFT (M1), the selection control line P2 of the organic EL element A is connected to the gate terminal of the TFT (M3), and the selection control line P3 of the organic EL element B is the TFT (M4). Is connected to the gate terminal. The data line is connected to the drain terminal of the TFT (M1), and voltage data Vdata is input from the data line as a data signal. The anode electrode of the organic EL element A is connected to the source terminal of the TFT (M3), and the cathode electrode is connected to the ground potential CGND. The anode electrode of the organic EL element B is connected to the source terminal of the TFT (M4), and the cathode electrode is connected to the ground potential CGND. The drain terminal of the TFT (M3) is connected to the drain terminal of the TFT (M2), and the source terminal of the TFT (M2) is connected to the power supply potential. The drain terminal of the TFT (M4) is connected to the drain terminal of the TFT (M5), and the source terminal of the TFT (M5) is connected to the power supply potential. The source terminal of the TFT (M1) is connected to one end of the capacitor C1 and the gate terminal of the TFT (M2). The other end of the capacitor C1 is connected to the power supply potential.

  In the present embodiment, in order to obtain a desired white balance, the data line 85 in FIG. 7A writes the same data signal to the organic EL elements A and B of the same color, and the organic EL element A in each pixel circuit. -The luminance ratio of each color in B is varied. Means for varying the luminance ratio of each color in the organic EL elements A and B in each pixel circuit are M2 and M5, which have different transistor sizes (W / L ratios) in FIG. In this case, the current drive capability differs between the organic EL elements A and B.

  Here, it is assumed that the current drive capability of the TFT (M2) of the R pixel is DR1, the current drive capability of the TFT (M2) of the G pixel is DG1, and the current drive capability of the TFT (M2) of the B pixel is DB1. Also, the current drive capability of the R pixel TFT (M5) is DR2, the current drive capability of the G pixel TFT (M5) is DG2, and the current drive capability of the B pixel TFT (M5) is DB2. In FIG. 8, DR1: DG1: DB1 and DR2: DG2: DB2, which are current drive capability ratios, are different. By making DR1: DG1: DB1 and DR2: DG2: DB2 different, it is possible to adjust the white balance by making the drive currents different in the organic EL elements A and B. That is, even if the same voltage data Vdata is input as a data signal to the R pixel, G pixel, and B pixel, the luminance balance of the R pixel, G pixel, and B pixel can be changed according to the current drive capability ratio. The white balance can be adjusted to a desired value.

  When obtaining a desired white balance, the drive current ratio required for the R pixel, G pixel, and B pixel is IR1: IG1: IB1 for the organic EL element A, and IR2: IG2: IB2 for the organic EL element B. In this case, DR1: DG1: DB1 = IR1: IG1: IB1, or DR2: DG2: DB2 = IR2: IG2: IB2. At this time, the luminance is LR1: LG1: LB1 ≠ LR2: LG2: LB2. LR1 is the luminance of the organic EL element A in the R pixel, LG1 is the luminance of the organic EL element A in the G pixel, and LB1 is the luminance of the organic EL element A in the B pixel. LR2 is the luminance of the organic EL element B in the R pixel, LG2 is the luminance of the organic EL element B in the G pixel, and LB2 is the luminance of the organic EL element B in the B pixel. That is, the luminance ratio of each color in the organic EL elements A and B is varied so that LR1: LG1: LB1 ≠ LR2: LG2: LB2.

  Next, the operation of the pixel circuit of FIG. 8 will be described with reference to the timing chart of FIG. In FIG. 9, the horizontal axis indicates time, and the vertical axis indicates ON (HI) / OFF (LOW) of P1 to P3. P2 and P3 are signals for controlling the light emission of the organic EL elements A and B.

  The data writing period in FIG. 9 will be described.

  During this period, a HI level signal is input to P1, a LOW level signal is input to P2 and P3, M1 is turned on, and M3 and M4 are turned off. At this time, since M3 and M4 are not conductive, no current flows through the organic EL elements A and B. A voltage corresponding to the current driving capability of M1 is generated at V1 by C1 disposed between the gate terminals of M2 and M5 and the power supply potential V1. That is, a data signal is written (Vdata is input). In the above description, M1, M3, and M4 are nMOS, and M2 is a pMOS. However, when M1, M3, and M4 are pMOS, it is necessary to reverse the HI / LOW levels.

  The light emission period in FIG. 9 will be described.

  When supplying current to the organic EL element A, a LOW level signal is input to P1, a HI level signal is input to P2, and a LOW level signal is input to P3. M1 is OFF, M3 is ON, and M4 is OFF. At this time, since M3 is in a conducting state, a current corresponding to the current driving capability of M2 is supplied to the organic EL element A by the voltage generated in C1, and the organic EL element A has a luminance corresponding to the supplied current. Emits light. During the period when P2 is at the HI level, the organic EL element A emits light, and the integrated light amount becomes the luminance of the organic EL element A.

  When supplying a current to the organic EL element B, a LOW level signal is input to P1, a LOW level signal is input to P2, and an HI level signal is input to P3. M1 is OFF, M3 is OFF, and M4 is ON. At this time, since M4 is in a conductive state, a current corresponding to the current driving capability of M5 is supplied to the organic EL element B by the voltage generated in C1, and the organic EL element B has a luminance corresponding to the supplied current. Emits light. During the period when P3 is at the HI level, the organic EL element B emits light, and the integrated light amount becomes the luminance of the organic EL element B.

  In the present embodiment, the luminance ratio of each color in the organic EL elements A and B can be made different by the above operation of the pixel circuit of FIG. 8, so that white balance can be adjusted and high image quality can be realized.

  In the present embodiment, it is more preferable that the lighting times are different in the organic EL elements A and B of the same color in that display according to the user scene can be performed and high image quality can be realized. Means for making the lighting times of the organic EL elements A and B of the same color different in each pixel circuit are P2 and M3, and P3 and M4 in FIG. Hereinafter, this more preferable aspect is demonstrated.

  In this embodiment, the front luminance when the same current is supplied to the organic EL elements A and B to emit light by the microlens arranged on the light emission surface side of the organic EL element B is the sub-pixel including the organic EL element A. : Sub-pixel including organic EL element B = 1: 4. At this time, the ratio of the current / time product per frame of the organic EL element A and the organic EL element B = 5: 0, 3: 1, 2: 2, 1: 3, 0: 4 (FIG. 9 ( a) to (e)). The lighting time of the organic EL element A and the organic EL element B is set in consideration of the ratio of the front luminance and the ratio of the current / time product.

  First, a case where “wide viewing angle mode” and “power saving mode” can be selected will be described. From the ratio of the front luminance and the current / time product ratio, the organic EL elements A and B have five lighting time ratios of 16: 0, 12: 1, 8: 2, 4: 3, and 0: 4. Become. In this embodiment, each of the two organic EL elements that emit the same color is connected separately, and has means for separately controlling the lighting / turning off of each of the two organic EL elements. It is possible to set M3 and M4 ON / OFF so as to satisfy the time ratio. In this case, as described in the first embodiment, the “wide viewing angle mode” and the “power saving mode” can be selected, and the intermediate between the “wide viewing angle mode” and the “power saving mode” can be selected. High image quality can be realized because various states can be selected.

  Next, a case where “wide viewing angle mode” and “outdoor visibility mode” can be selected will be described. From the ratio of the front luminance and the current / time product ratio, the organic EL elements A and B have five lighting time ratios of 4: 0, 3: 4, 2: 8, 1:12, and 0:16. Become. In this embodiment, each of the two organic EL elements that emit the same color is connected separately, and has means for separately controlling the lighting / turning off of each of the two organic EL elements. It is possible to set M3 and M4 ON / OFF so as to satisfy the time ratio. When lit in this way, as described in the first embodiment, “wide viewing angle mode” and “outdoor visibility mode” can be selected, and “wide viewing angle mode” and “outdoor visibility mode” can be selected. Since an intermediate state can be selected, high image quality can be realized.

  In this embodiment, since the instantaneous current supplied when the organic EL elements A and B are turned on is constant, the pixel circuit can drive the organic EL elements A and B with the same current value. Specifically, in the case where only one of the organic EL elements A and B emits light as shown in FIGS. 9A and 9E, the input data signal may have the same value, so that it is supplied to the organic EL element B. The dynamic range of the data signal to be processed can be widened, and the S / N ratio can be increased. 9B to 9D, since the current value can be driven with the same value, both the organic EL elements A and B can be driven with one writing of the data signal of the pixel circuit.

[Example 2]
FIG. 10 is a schematic view of an organic EL panel 80 having a plurality of pixels (m rows and n columns pixels) arranged in a matrix, and an organic EL element is arranged in each pixel. It is. The organic EL panel 80 includes an organic EL element (not shown), a data line driving circuit 81 (data line driver), a gate line driving circuit 82 (gate line driver), a pixel circuit 83, and a gate line driving circuit 84 (gate line driver). . The data line driving circuit 81 applies a data signal to the data line 85. The gate line driving circuit 82 drives the gate lines P1 and P2. The pixel circuit 83 is disposed in each pixel, has a plurality of transistors, supplies a drive current corresponding to the data signal to the organic EL element, and turns on the organic EL element. The gate line driving circuit 84 drives the gate line (selection control line) P3 in the display area. Each pixel has two sub-pixels that emit R and have different optical characteristics, two sub-pixels that emit G and have different optical characteristics, and two sub-pixels that emit B and have different optical characteristics. Each subpixel includes an organic EL element. In FIG. 10, the gate line driving circuit 82 and the gate line driving circuit 84 in the display area are arranged on the left and right sides of the pixel group. However, the gate line driving circuit 82 and the gate line driving circuit 84 in the display area may be arranged on either the left or right side. In order to improve, the same function may be arranged on both the left and right sides and driven from both sides. Since the pixel configuration and pixel arrangement of the display device of this embodiment are the same as those in FIGS. 7B and 7C, description thereof will be omitted.

  FIG. 11 shows a pixel circuit of this embodiment. The gate lines P1 and P2 are connected to the gate terminal of the TFT (M1) and the gate terminal of the TFT (M5), respectively. Both selection control lines P3 of the organic EL elements A and B are connected to the gate terminal of the TFT (M3) and the gate terminal of the TFT (M4). The data line is connected to one end of the capacitor C1 and one end of the capacitor C2, and voltage data Vdata is input from the data line as a data signal. Different data signals V1 and V2 generated by the data line driving circuit 81 in FIG. 10 are supplied from the data line to one end of the capacitor C1 and one end of the capacitor C2. The anode electrode of the organic EL element A is connected to the source terminal of the TFT (M3), and the cathode electrode is connected to the ground potential CGND. The anode electrode of the organic EL element B is connected to the source terminal of the TFT (M4), and the cathode electrode is connected to the ground potential CGND. The drain terminal of the TFT (M3) is connected to the source terminal of the TFT (M1) and the drain terminal of the TFT (M2), and the source terminal of the TFT (M2) is connected to the power supply potential. The drain terminal of the TFT (M4) is connected to the source terminal of the TFT (M5) and the drain terminal of the TFT (M6), and the source terminal of the TFT (M6) is connected to the power supply potential. The drain terminal of the TFT (M1) is connected to the gate terminal of the TFT (M2) and the other end of the capacitor C1, and the drain terminal of the TFT (M5) is connected to the gate terminal of the TFT (M6) and the other end of the capacitor C2. Yes.

  Here, means for generating different data signals Vdata = V1, V2 in the data line driving circuit 81 of FIG. 10 will be described. Two processing blocks may be prepared as means for generating different data signals. FIG. 12 shows a configuration example of means for generating two data signals from one image data. When image data is input to two processing blocks, for example, data processing is performed for the organic EL element A in the processing 1 block to generate a data signal, and data processing is performed for the organic EL element B in the processing 2 block. Generate a data signal. In the processing block, the data signal may be generated by analog processing using a resistance ladder circuit in which the resistance ratio is changed to that for the organic EL element A or the organic EL element B, and the data after the digital signal processing is processed by the DA converter. A signal may be generated. The generated data signal for the organic EL element A and the data signal for the organic EL element B are switched by a switch and output to the data line.

  In this embodiment, in order to obtain a desired white balance, each data signal is generated for the organic EL elements A and B of the same color by the data line driving circuit 81 in FIG. Write. Thereby, the luminance ratio of each color in the organic EL elements A and B is varied. In the data line driving circuit 81, the means for making the luminance ratios of the respective colors of the organic EL elements A and B different from each other is such that different data signals are applied to the gate terminals of the driving transistors included in the organic EL elements A and B of the same color in FIG. Means for generating and supplying. By making the data signals different, it is possible to adjust the white balance by making the drive currents different in the organic EL elements A and B.

  The current drive capability ratio of the organic EL elements A and B is as described in the first embodiment. When obtaining a desired white balance, the data signals corresponding to the organic EL elements A in the R pixel, G pixel, and B pixel and the organic EL elements B in the R pixel, G pixel, and B pixel are different from each other. Make it. The drive current ratio required for the R pixel, G pixel, and B pixel is IR1: IG1: IB1 for the organic EL element A, and IR2: IG2: IB2 for the organic EL element B. In this case, IR1 / IR2 ≠ IG1 / IG2 ≠ IB1 / IB2. At this time, the luminance is LR1 / LR2 ≠ LG1 / LG2 ≠ LB1 / LB2. LR1 is the luminance of the organic EL element A in the R pixel, LG1 is the luminance of the organic EL element A in the G pixel, and LB1 is the luminance of the organic EL element A in the B pixel. LR2 is the luminance of the organic EL element B in the R pixel, LG2 is the luminance of the organic EL element B in the G pixel, and LB2 is the luminance of the organic EL element B in the B pixel. That is, the luminance ratio of each color in the organic EL elements A and B is made different so that LR1 / LR2 ≠ LG1 / LG2 ≠ LB1 / LB2.

  Next, the operation of the pixel circuit in FIG. 11 will be described with reference to timing charts in FIGS. 13A and 13B, the horizontal axis represents time, the vertical axis represents ON (HI) / OFF (LOW) of P1 to P3, the voltage of the data line, the gate potential M2g of M2, and the gate potential M6g of M6. Show.

  FIG. 13A is a timing chart showing writing and light emission operations in one frame. A period from t1 to t2 is a writing period for each row, and a period from t2 to t3 is a light emitting period for all rows.

  First, the writing period (t1 to t2) in FIG. As for P3, a pulse is output from the gate line driving circuit 82 at any time so that writing is performed every horizontal period. Two HI pulses are output from P3 (a) in the corresponding row to be written, for example, row a. A data signal Vdata is output from the data line. In the corresponding row, the data signal Vdata is output from the data line driving circuit 81 in the order of the organic EL element A and the organic EL element B.

  A detailed operation of writing in the pixel circuit will be described with reference to FIG.

  In the period from t4 to t5, the data signal Vdata = V1 written to the organic EL element A is output to the data line.

  In the period from t5 to t6, P1 (a) and P3 (a) are HI, and M1 and M3 are in the ON state. The gate terminal of M2 has the same potential (V4) as the anode electrode of the organic EL element A. At this time, since current flows through the organic EL element A, light is emitted, but this period is controlled so as not to cause a problem.

  In a period from t6 to t7, M3 is in an OFF state. At this time, M1 remains in an ON state, and M2 is in a diode connection state. During the period from t5 to t6, the gate potential of M2 converges from V4 to a voltage (V3) obtained by subtracting the threshold voltage Vth of M2 from the power supply potential (hereinafter referred to as Voled).

  In the period from t7 to t8, P1 (a) is LOW and M1 is in the OFF state. At this time, a difference voltage of V1 and Voled−Vth is stored between the capacitors C1, and the writing operation to the organic EL element A is completed. The data line outputs a data signal Vdata = V2 written to the organic EL element B to the data line.

  In the period from t8 to t9, P2 (a) and P3 (a) are HI, and M5 and M4 are in the ON state. The gate terminal of M6 has the same potential (V6) as the anode electrode of the organic EL element B. At this time, since current flows through the organic EL element A, light is emitted, but this period is controlled so as not to cause a problem.

  In a period from t9 to t10, M4 is in an OFF state. At this time, M5 remains in an ON state, and M6 is in a diode connection state. During the period from t8 to t9, the gate potential of M6 converges from V6 to a voltage (V5) obtained by subtracting the threshold voltage Vth of M6 from the power supply potential (hereinafter referred to as Voled).

  In the period from t10 to t11, P2 (a) is LOW and M5 is in the OFF state. At this time, a difference voltage of V2 and Voled−Vth is stored between the capacitors C2, and the writing operation to the organic EL element B is completed.

  After t11, the writing period of another row starts. The data line changes according to the data signal of the target pixel. The gate potential of M2 and the gate potential of M6 change according to the change of the data line, but the potential difference between the capacitors C1 and C2 changes while maintaining the state at the time of writing.

  Next, the light emission period (t2 to t3) in FIG. When writing is completed up to the m-th row, P3 (1 to m) of all rows simultaneously output HI pulses during the light emission period. The signal Vdata output to the data line becomes a fixed potential Vref. The gate potential of M2 and the gate potential of M6 change according to the write signal of the other row while maintaining the potential difference between the capacitor terminals at the time of writing, but in the state where the voltage Vref at the time of light emission is determined, V3- ( V1-Vref) and V5- (V2-Vref).

A voltage-current characteristic of a TFT is generally expressed by β (current amplification factor) × (Vgs (gate-source voltage) −Vth) ² . From this equation, a current Id1 flowing through the organic EL element A is calculated. The gate potential of M2 is (Voled−Vth) − (V1−Vref), and the voltage of Vgs is Voled− (Voled−Vth− (V1−Vref)), that is, Vgs = Vth + V1−Vref. Therefore,
Id1 = β (current amplification factor) × (V1−Vref) ² (Formula 1)
It becomes. Similarly, the current Id2 flowing through the organic EL element B is
Id2 = β (current amplification factor) × (V2−Vref) ² (Formula 2)
It becomes.

  In the present embodiment, the luminance ratio of each color in the organic EL elements A and B can be made different by the above operation of the pixel circuit of FIG. 11, so that white balance can be adjusted and high image quality can be realized.

  In the present embodiment, it is more preferable that the organic EL elements A and B of the same color have the same lighting time and different drive currents because display according to the user scene can be performed and high image quality can be realized. More specifically, the data line driving circuit 81 shown in FIG. 10 generates data signals for the organic EL elements A and B of the same color and writes different signals to the data lines 85, whereby the organic EL elements A of the same color are written. This can be realized by changing the drive current supplied to B. This can be realized by means for generating and supplying different data signals to the gate terminals of the drive transistors of the organic EL elements A and B of the same color. Hereinafter, this more preferable aspect is demonstrated.

  In this embodiment, the front luminance when the same current is supplied to the organic EL elements A and B to emit light by the microlens arranged on the light emission surface side of the organic EL element B is the sub-pixel including the organic EL element A. : Sub-pixel including organic EL element B = 1: 4. At this time, the ratio of the current / time product per frame of the organic EL element A and the organic EL element B = 5: 0, 3: 1, 2: 2, 1: 3, 0: 4. The drive currents of the organic EL element A and the organic EL element B are set in consideration of the ratio of the front luminance and the ratio of current / time product.

  First, a case where “wide viewing angle mode” and “power saving mode” can be selected will be described. From the ratio of the front luminance and the current / time product ratio, the organic EL elements A and B have five drive current ratios of 16: 0, 12: 1, 8: 2, 4: 3, and 0: 4. Become. In this embodiment, since there are means for generating and supplying different data signals to the gate terminals of the respective drive transistors provided for each of the two organic EL elements emitting the same color, the above five drive current ratios are satisfied. The data signals V1 and V2 can be set. In this case, as described in the second embodiment, the “wide viewing angle mode” and the “power saving mode” can be selected, and the intermediate between the “wide viewing angle mode” and the “power saving mode” can be selected. High image quality can be realized because various states can be selected.

  Next, a case where “wide viewing angle mode” and “outdoor visibility mode” can be selected will be described. From the front luminance ratio and the current / time product ratio, the organic EL elements A and B have five drive current ratios of 4: 0, 3: 4, 2: 8, 1:12, and 0:16. Become. In this embodiment, since there are means for generating and supplying different data signals to the gate terminals of the respective drive transistors provided for each of the two organic EL elements emitting the same color, the above five drive current ratios are satisfied. The data signals V1 and V2 can be set. In this case, as described in the second embodiment, “wide viewing angle mode” and “outdoor visibility mode” can be selected, and “wide viewing angle mode” and “outdoor visibility mode” can be selected. Since an intermediate state can be selected, high image quality can be realized.

  Further, in this embodiment, a process in which the threshold value of each TFT has a manufacturing variation can be driven by Vth from the above formulas 1 and 2, and the variation is suppressed and the quality is stable. Can be driven.

Example 3
The organic EL panel of this embodiment is the same as that shown in FIG. 10, and the pixel configuration and pixel arrangement of the display device of this embodiment are the same as those shown in FIGS.

  FIG. 14 shows a pixel circuit of this embodiment, which is partially different from the pixel circuit of FIG. 11 differs from the pixel circuit in FIG. 11 in that the gate line P1 is connected to the gate terminal of the TFT (M5), the TFT (M7), the TFT (M8), the TFT (M9), the TFT (M10), and the voltage line. Vref1 and voltage line Vref2 are added. The drain terminal of the TFT (M7) is connected to the data line, and the source terminal of the TFT (M7) is connected to one end of the capacitor C1. The source terminal of the TFT (M8) is connected to the voltage line Vref1, and the drain terminal of the TFT (M8) is connected to one end of the capacitor C1. The drain terminal of the TFT (M9) is connected to the data line, and the source terminal of the TFT (M9) is connected to one end of the capacitor C2. The source terminal of the TFT (M10) is connected to the voltage line Vref2, and the drain terminal of the TFT (M10) is connected to one end of the capacitor C2. The gate terminal of the TFT (M7), the gate terminal of the TFT (M8), the gate terminal of the TFT (M9), and the gate terminal of the TFT (M10) are connected to the gate line P1. When one of the TFT (M7) and the TFT (M8) or the TFT (M9) and the TFT (M10) is in the ON state, the other is in the OFF state, and the TFTs operate in a complementary manner.

  In this embodiment, in order to obtain a desired white balance, the luminance ratio of each color for the organic EL element A and the luminance ratio of each color for the organic EL element B are made different. Specifically, the data line 85 in FIG. 7A writes the same data signal to the organic EL elements A and B of the same color, and the luminance ratio of each color in the organic EL elements A and B is different in each pixel circuit. Make it. The means for varying the luminance ratio of each color in the organic EL elements A and B in each pixel circuit is the voltages Vref1 and Vref2 applied to the gate terminal of M2 and the gate terminal of M6 in FIG. By varying the voltage, the white balance can be adjusted by varying the drive current in the organic EL elements A and B. The current drive capability ratio, drive current ratio, and luminance of the organic EL elements A and B are as described in the second embodiment.

  Next, the operation of the pixel circuit in FIG. 14 will be described with reference to timing charts in FIGS. 15A and 15B, the horizontal axis represents time, the vertical axis represents ON (HI) / OFF (LOW) of P1 and P3, the voltage of the data line, the gate potential M2g of M2, and the gate potential M6g of M6. Show.

  FIG. 15A is a timing chart showing a writing operation and a light emitting operation in one frame. From t1 to t2 is the writing period of the first row, and from t2 to t3 is the light emitting period of the first row and the writing period of rows other than the first row. After the sequential writing operation from the first row to the m-th row, the light emission operation is performed, and after the m-th row, the operation is sequentially repeated again from the first row. A data signal Vdata is output to the data line.

  A detailed operation of writing in the pixel circuit will be described with reference to FIG.

  In the period from t4 to t5, the data signal Vdata = V1 is output to the data line.

  In the period from t5 to t6, P1 (a) and P3 (a) are HI, and M1, M3, M4, M5, M7, and M9 are in an ON state. The gate potential of M2 becomes the same potential (V4) as the anode electrode of the organic EL element A. The gate potential of M6 becomes the same potential (V6) as the anode electrode of the organic EL element B. At this time, the current flows through the organic EL element A and the organic EL element B, so that light is emitted, but this period is controlled so as not to cause a problem. Further, one end of the capacitors C1 and C2 is the data signal Vdata = V1.

  In the period from t6 to t7, M3 and M4 are in an OFF state. At this time, M1 and M5 remain in an ON state, and M2 and M6 are in a diode connection state. During the period from t5 to t6, the gate potential of M2 converges from V4 to a voltage (V3) obtained by subtracting the threshold voltage Vth1 of M2 from the power supply potential (hereinafter referred to as Voled). The gate potential of M6 converges from V4 to a voltage (V5) obtained by subtracting the threshold voltage Vth2 of M6 from the power supply potential (hereinafter referred to as Voled).

  In the period from t7 to t8, P1 (a) is LOW, and M1, M5, M7, and M9 are in the OFF state. At this time, the differential voltage of V1 and Voled−Vth1 is stored between the capacitors C1, and the writing operation to the organic EL element A is completed. At the same time, a difference voltage of V1 and Voled−Vth2 is stored between the capacitors C2, and the writing operation to the organic EL element B is also completed. Further, since M8 and M10 are turned on, one end of the capacitor C1 becomes the voltage Vref1, and one end of the capacitor C2 becomes the voltage Vref2. The potential difference between the capacitors C1 and C2 varies while maintaining the state at the time of writing. As a result, the gate potential of M2 and the gate potential of M6 are V3- (V1-Vref1) and V5- (V1-Vref2), respectively. .

  After t8, P3 (a) becomes HI, and the light emission operation is performed in the a-th row. In addition, the writing period of the next row (a + 1 row) is started.

A voltage-current characteristic of a TFT is generally expressed by β (current amplification factor) × (Vgs (gate-source voltage) −Vth) ² . From this equation, a current Id1 flowing through the organic EL element A is calculated. The gate potential of M2 is Vg = (Voled−Vth1) − (V1−Vref1), and the voltage of Vgs is Voled− (Voled−Vth1− (V1−Vref)), that is, Vgs = Vth1 + V1−Vref. Therefore,
Id1 = β × (V1−Vref1) ² (Formula 3)
It becomes. Similarly, the current Id2 flowing through the organic EL element B is Id2 = β × (V1−Vref2) ² (Formula 4)
It becomes.

  In the present embodiment, the luminance ratio of each color in the organic EL elements A and B can be made different by the above-described operation of the pixel circuit of FIG. 14, so that white balance can be adjusted and high image quality can be realized.

  In the present embodiment, it is more preferable that the organic EL elements A and B of the same color have the same lighting time and different drive currents because display according to the user scene can be performed and high image quality can be realized. Specifically, the data line 85 in FIG. 10 writes the same data signal to the organic EL elements A and B of the same color, and the drive current supplied to the organic EL elements A and B of the same color is different in each pixel circuit. Can be realized. This can be realized by means for supplying different voltages (reference voltages) to the gate terminals of the drive transistors of the organic EL elements A and B of the same color. Hereinafter, this more preferable aspect is demonstrated.

  In this embodiment, the front luminance when the same current is supplied to the organic EL elements A and B to emit light by the microlens arranged on the light emission surface side of the organic EL element B is the sub-pixel including the organic EL element A. : Sub-pixel including organic EL element B = 1: 4. At this time, the ratio of the current / time product per frame of the organic EL element A and the organic EL element B = 5: 0, 3: 1, 2: 2, 1: 3, 0: 4. The drive currents of the organic EL element A and the organic EL element B are set in consideration of the ratio of the front luminance and the ratio of current / time product.

  First, a case where “wide viewing angle mode” and “power saving mode” can be selected will be described. From the ratio of the front luminance and the current / time product ratio, the organic EL elements A and B have five drive current ratios of 16: 0, 12: 1, 8: 2, 4: 3, and 0: 4. Become. In this embodiment, since there are means for supplying different voltages to the gate terminals of the respective drive transistors for each of the two organic EL elements that emit the same color, the voltage Vref1, which satisfies the above five drive current ratios, Vref2 can be set. In this case, as described in the third embodiment, the “wide viewing angle mode” and the “power saving mode” can be selected, and the intermediate between the “wide viewing angle mode” and the “power saving mode” can be selected. High image quality can be realized because various states can be selected.

  Next, a case where “wide viewing angle mode” and “outdoor visibility mode” can be selected will be described. From the front luminance ratio and the current / time product ratio, the organic EL elements A and B have five drive current ratios of 4: 0, 3: 4, 2: 8, 1:12, and 0:16. Become. In this embodiment, since there are means for supplying different voltages to the gate terminals of the respective drive transistors for each of the two organic EL elements that emit the same color, the voltage Vref1, which satisfies the above five drive current ratios, Vref2 can be set. When lit in this way, as described in the third embodiment, “wide viewing angle mode” and “outdoor visibility mode” can be selected, and “wide viewing angle mode” and “outdoor visibility mode” can be selected. Since an intermediate state can be selected, high image quality can be realized.

  Further, in this embodiment, a process in which the threshold value of each TFT has a manufacturing variation can be driven by Vth from the above equations 3 and 4, and the variation is suppressed and the quality is stable. Can be driven.

  Since the voltage Vref1 and the voltage Vref2 are different, different currents Id1 and Id2 can be supplied to the organic EL element A and the organic EL element B even if M2 and M6 write the same current amplification factor β and the same data signal V1. It becomes possible.

Example 4
The organic EL panel of this embodiment is the same as that shown in FIG. 10, and the pixel configuration and pixel arrangement of the display device of this embodiment are the same as those shown in FIGS.

  FIG. 16 shows a pixel circuit of this embodiment, which is partially different from the pixel circuit of FIG. 11 differs from the pixel circuit of FIG. 11 in that a gate line P1 is connected to the gate terminal of the TFT (M5) and a capacitor C3 is connected between the source terminal and the gate terminal of the TFT (M6). is there.

  In this embodiment, in order to obtain a desired white balance, the luminance ratio of each color for the organic EL element A and the luminance ratio of each color for the organic EL element B are made different. Specifically, the data line 85 in FIG. 7A writes the same data signal to the organic EL elements A and B of the same color, and the luminance ratio of each color in the organic EL elements A and B is different in each pixel circuit. Make it. Means for varying the luminance ratio of each color in the organic EL elements A and B in each pixel circuit is a capacitor C3 connected between the source terminal and the gate terminal of the TFT (M6) in FIG. By reducing the pressure and making the data signals different, it is possible to adjust the white balance by making the drive currents different in the organic EL elements A and B. The current drive capability ratio, drive current ratio, and luminance of the organic EL elements A and B are as described in the second embodiment.

  Next, the operation of the pixel circuit in FIG. 16 will be described with reference to timing charts in FIGS. 17A and 17B, the horizontal axis represents time, the vertical axis represents ON (HI) / OFF (LOW) of P1 and P3, the voltage of the data line, the gate potential M2g of M2, and the gate potential M6g of M6. Show.

  FIG. 17A is a timing chart showing a writing operation and a light emitting operation in one frame. The period from t1 to t2 is a writing period for each row, and the period from t2 to t3 is a light emission period for all the lines.

  First, the writing period (t1 to t2) in FIG. A pulse is output from the gate line driving circuit 82 at any time so that writing is performed on the gate line P3 every horizontal period. One HI pulse is output from P3 (a) in the corresponding row to be written, for example, row a. A data signal Vdata is output to the data signal line.

  The detailed operation of writing in the pixel circuit will be described with reference to FIG.

  In the period from t4 to t5, the data signal Vdata = V1 is output to the data signal line.

  In the period from t5 to t6, P1 (a) and P3 (a) become HI, and the TFT (M1), TFT (M3), TFT (M4), and TFT (M5) are turned on. The gate potential M2g of the TFT (M2) becomes the same potential (V4) as the anode electrode of the organic EL element A. The gate potential M6g of the TFT (M6) is the same potential (V6) as the anode electrode of the organic EL element B. At this time, the current flows through the organic EL element A and the organic EL element B, so that light is emitted, but this period is controlled so as not to cause a problem.

  In the period from t6 to t7, the TFT (M3) and the TFT (M4) are turned off. At this time, the TFT (M1) and the TFT (M5) remain in the ON state, and the TFT (M2) and the TFT (M6) are in a diode connection state. In the period from t5 to t6, the gate potential of the TFT (M2) converges to a voltage (V3) obtained by subtracting the threshold voltage Vth1 of the TFT (M2) from the power supply potential (hereinafter referred to as Voled) from V4. The gate potential of the TFT (M6) converges to a voltage (V5) obtained by subtracting the threshold voltage Vth2 of the TFT (M6) from the power supply potential (hereinafter referred to as Voled) from V4.

  In the period from t7 to t8, P1 (a) is LOW, and the TFT (M1) and the TFT (M5) are in the OFF state. At this time, the voltage difference between V1 and Voled−Vth1 is stored between the capacitors C1, and the writing operation to the organic EL element A is completed. At the same time, a difference voltage of V1 and Voled−Vth2 is stored between the capacitors C2, and the writing operation to the organic EL element B is also completed.

  After t8, the writing period for another row starts. The data signal line changes in accordance with the data signal of the target pixel. The gate potentials of the TFT (M2) and TFT (M6) change according to the change of the data signal line, but the potential difference between the capacitors C1 and C2 varies while maintaining the state at the time of writing.

  Next, the light emission period (t2 to t3) in FIG. When writing is completed up to the m-th row, P3 (1 to m) of all rows simultaneously output HI pulses during the light emission period. The signal Vdata output to the data signal line becomes the fixed potential Vref. The gate potentials of the TFT (M2) and TFT (M6) change in accordance with the write signal of the other row while maintaining the potential difference between the capacitor terminals at the time of writing, but in the state determined as the voltage Vref at the time of light emission, respectively. It becomes as follows. The gate potential of the TFT (M2) is V3- (V1-Vref), and the gate potential of the TFT (M6) is V5- (V1-Vref) × C2 / (C2 + C3). The gate potential of the TFT (M6) is divided by the capacitance ratio of the capacitors C2 and C3 because it has the capacitor C3.

The voltage-current characteristic of a TFT is generally expressed by β (current amplification factor) × (Vgs (gate-source voltage) −Vth) ² . From this equation, a current Id1 flowing through the organic EL element A is calculated. The gate potential of M2 is Vg = (Voled−Vth1) − (V1−Vref), and the voltage of Vgs is Voled− (Voled−Vth1− (V1−Vref)), that is, Vgs = Vth1 + V1−Vref. Therefore,
Id1 = β × (V1−Vref) ² (Formula 5)
It becomes. Similarly, the current Id2 flowing through the organic EL element B is
Id2 = β × {(V1−Vref) × C2 / (C2 + C3)} ² (Formula 6)
It becomes.

  In the present embodiment, the luminance ratio of each color in the organic EL elements A and B can be varied by the above-described operation of the pixel circuit of FIG. 16, so that white balance can be adjusted and high image quality can be realized.

  Further, in this embodiment, a process in which the threshold value of each TFT has a manufacturing variation can be driven by Vth from the above formulas 5 and 6, and the variation is suppressed and the quality is stable. Can be driven.

  A capacitor C3 is provided between the gate terminal and the source terminal of the TFT (M6). Therefore, even if TFT (M2) and TFT (M6) write the same current amplification factor β and the same data signal V1, different currents Id1 and Id2 can flow through organic EL element A and organic EL element B. It becomes. Further, a capacitance C4 may be provided between the gate terminal and the source terminal of the TFT (M2), and the capacitance ratios C1 / C4 and C2 / C3 may be different.

  In this way, by setting the capacitance to a desired value, even if the same data signal is input to the pixel circuit, the current flowing through the organic EL element A and the organic EL element B can be made different. A display device with high image quality that can be easily adjusted can be provided.

  DESCRIPTION OF SYMBOLS 11, 80: Organic EL panel, 12, 81: Data line drive circuit, 13, 82: Gate line drive circuit, 14, 83: Pixel circuit, 20: Substrate, 21: Anode electrode, 22: Pixel separation layer, 23: Organic compound layer (organic EL layer), 24: cathode electrode, 25: protective layer, 31, 101: R pixel, 32, 102: G pixel, 33, 103: B pixel, 311, 1011: R-1 of R pixel Subpixels 312, 1012: R-2 subpixel of R pixel, 321, 1021: G-1 subpixel of G pixel, 322, 1022: G-2 subpixel of G pixel, 331, 1031: B of B pixel -1 sub-pixel, 332, 1032: B-2 sub-pixel of B pixel, 84: gate line driving circuit of display area, 111: microlens

Claims (9)

A plurality of pixels arranged in a matrix;
An organic EL element disposed in each of the pixels;
A data line driver for supplying a data signal corresponding to image data to each pixel;
A pixel circuit disposed in each of the pixels, having a plurality of transistors, supplying a driving current corresponding to a data signal to the organic EL element, and lighting the organic EL element;
A gate line driver for driving the transistors;
An organic EL display device comprising:
Each of the pixels is a pixel that has three or more organic EL element groups including two organic EL elements that emit the same color, and emits three or more colors.
The two organic EL elements are a first organic EL element in which an element having a high light condensing property is disposed on the light emitting surface side, and a second organic EL element in which an element having a high light condensing property is not disposed on the light emitting surface side. Consists of
The organic EL display device according to claim 1, further comprising means for making the luminance ratio of each color for the first organic EL element different from the luminance ratio of each color for the second organic EL element in each of the pixels.   2. The organic EL display device according to claim 1, wherein the highly condensing element is a microlens. Each of the pixel circuits has a driving transistor for supplying a driving current in each of the first organic EL element and the second organic EL element of the same color,
The means for varying the luminance ratio is the driving transistor that supplies a driving current to each of the first organic EL element and the second organic EL element having different W / L ratios and having the same color. The organic EL display device according to claim 1 or 2. Each of the pixel circuits has a driving transistor for supplying a driving current in each of the first organic EL element and the second organic EL element of the same color,
The means for varying the luminance ratio is provided in the data line driver, and is means for generating and supplying different data signals to the gate terminals of the respective drive transistors. The organic EL display device described. Each of the pixel circuits has a driving transistor for supplying a driving current in each of the first organic EL element and the second organic EL element of the same color,
3. The organic EL display device according to claim 1, wherein the means for varying the luminance ratio is means for supplying different voltages to the gate terminals of the drive transistors. Each of the pixel circuits has a driving transistor for supplying a driving current in each of the first organic EL element and the second organic EL element of the same color,
3. The organic EL display device according to claim 1, wherein the means for varying the luminance ratio is a capacitor that has one end connected to a gate terminal of each driving transistor and depressurizes a data signal. 4.   4. The organic EL display device according to claim 3, further comprising means for making lighting times different between the first organic EL element and the second organic EL element of the same color.   The means for varying the lighting time is separately connected to each of the first organic EL element and the second organic EL element of the same color, and the first organic EL element and the second organic EL element of the same color are connected separately. 8. The organic EL display device according to claim 7, wherein the organic EL display device is means for separately controlling lighting and extinguishing of each.   6. The organic EL display device according to claim 4, further comprising means for differentiating a driving current between the first organic EL element and the second organic EL element of the same color.

Images